霍普夫分叉
控制理论(社会学)
理论(学习稳定性)
分叉
自适应控制
动力学(音乐)
反馈控制
人口
灵敏度(控制系统)
分叉理论的生物学应用
控制(管理)
振荡(细胞信号)
数学
复杂动力学
计算机科学
强迫(数学)
资源(消歧)
人口模型
应用数学
稳定性理论
计算机模拟
系统动力学
非正面反馈
倍周期分岔
非线性系统
强迫振荡
作者
Binyu Zhao,Yu Mu,Yuanshun Tan,Zijian Liu
标识
DOI:10.1142/s0218127426500100
摘要
In ecosystems, the interplay between resource dynamics and species evolution drives complex adaptive behaviors of species. This study proposes a novel delayed turbidostat model that integrates resource consumption-induced delay and dynamic feedback between species and resources, aiming to elucidate oscillation patterns observed in microbial cultivation. We first establish the existence and stability criteria for the positive equilibrium, identifying conditions for steady-state coexistence without delay. Bifurcation and sensitivity analysis for the control parameters reveals that it governs Hopf bifurcation-induced periodic solutions, aligning with experimental observations of population oscillations. Furthermore, the delay parameter is shown to destabilize the equilibrium through Hopf bifurcation, while adaptive control strategies effectively increase the critical delay threshold for bifurcation, mitigating its destabilizing effects. Numerical simulations validate the theoretical framework and uncover various stability regimes under the coupled effects of delay and control scheme. Our findings provide a mechanistic understanding of how feedback control can counteract time-delay disturbances, offering practical insights for optimizing bioreactor operations and ecological management.
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